Cooperativity and Dimerization of Recombinant Human Estrogen Receptor Hormone-binding Domain

Brandt, Mark E.; Vickery, Larry E.

doi:10.1074/jbc.272.8.4843

Cited by 48 publications

(45 citation statements)

References 32 publications

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“…The nonlinear terms can then be neglected to give α ≈ −a 3 (K)/a 2 (K), and a good approximation to K corresponding to the largest possible α is given by K c in (40). In contrast to earlier work by Collier et al [4], Wearing et al demonstrated that the juxtacrine model (1) can generate a wide range of pattern wavelengths.…”

Section: Fastest Growing Modesmentioning

confidence: 99%

“…In both the string and two-dimensional square arrays, K(λ) is bounded between ±1 as λ varies. However, K(λ) is reduced to [0,1] Substituting into the linearized model and dividing through by exp(αt + iλ · x), the condition for non-trivial solutions gives the cubic characteristic…”

Section: Linear Stability Analysismentioning

confidence: 99%

“…Each nicotinic receptor has two binding sites for acetylcholine, one of a group of biochemicals known as neurotransmitters that carry nerve impulses from one neuron to another. The estrogen receptor dimerizes and exhibits cooperative ligand binding as part of its normal functioning [1]. Another important co-operative behaviour is when the ligand is multivalent, such as platelet derived growth factor (PDGF) which can cross-link and bind to two or more receptors [9,11].…”

Section: Relation To the Model Of Collier Et Al [4]mentioning

confidence: 99%

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Oscillations and patterns in spatially discrete models for developmental intercellular signalling

Webb

Owen

2004

Journal of Mathematical Biology

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Abstract. We extend previous models for nearest neighbour ligand-receptor binding to include both lateral induction and inhibition of ligand and receptor production, and different geometries (strings of cells and hexagonal arrays, in addition to square arrays). We demonstrate the possibility of lateral inhibition giving patterns with a characteristic length scale of many cell diameters, when receptor production is included. In contrast, lateral induction combined with inhibition of receptor synthesis cannot give rise to a patterning instability under any circumstances. Interesting new dynamics include the analytical prediction and consequent numerical observation of spatiotemporal oscillations-this depends crucially on the production terms and on the relationship between the decay rates of ligand and free receptor.Our approach allows for a detailed comparison with the model for Delta-Notch interactions of Collier et al.[4], and we find that a formal reduction may be made only when the ligand receptor binding kinetics are very slow. Without such very slow receptor kinetics, spatial pattern formation via lateral inhibition in hexagonal cellular arrays requires significant activation of receptor production, a feature that is not apparent from previous analyses.

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Section: Fastest Growing Modesmentioning

confidence: 99%

Section: Linear Stability Analysismentioning

confidence: 99%

Section: Relation To the Model Of Collier Et Al [4]mentioning

confidence: 99%

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Oscillations and patterns in spatially discrete models for developmental intercellular signalling

Webb

Owen

2004

Journal of Mathematical Biology

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“…The 1:2 stoichiometry suggests that CaM may facilitate functional dimerization of ER-␣, which could help place two ER-␣ DNA binding domains in contact with tandem repeat sequences in ERE (36,37). The ER-␣ LBD (residues 305-552) forms a dimer in the x-ray crystal structure of the E2-bound state (12), whereas the E2-free apo-LBD has weaker dimerization affinity (38,39). Thus, ER-␣ dimerization stabilized by E2 binding may be important for activating transcription (3).…”

Section: Table 1 Itc Parameters For Cam Binding To Functional Fragmenmentioning

confidence: 99%

Structural Basis for Ca2+-induced Activation and Dimerization of Estrogen Receptor α by Calmodulin

Zhang

Sacks

et al. 2012

Journal of Biological Chemistry

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“…However, in reality the actual binding model could be more complicated because liganded ER is typically dimeric and therefore capable of binding two peptide motifs (one for each LBD in an ER homodimer). Based on the reported equilibrium constants for ER dimerization (37,38), we have assumed that, at the concentrations of ER and ER␣LBD used in this study (Ն16 nM), the receptor exists as a homodimer. To further simplify the system, we also immobilized limited amounts of each peptide to the chip surfaces so as to make it impossible for two peptides to bind simultaneously to a single ER homodimer.…”

Section: Spr Analysis Of Er␣lbd/lxxll Peptide Interactions-mentioning

confidence: 99%

Interaction of Transcriptional Intermediary Factor 2 Nuclear Receptor Box Peptides with the Coactivator Binding Site of Estrogen Receptor α

Wärnmark¹,

Treuter²,

Gustafsson³

et al. 2002

Journal of Biological Chemistry

155

159

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The activation function 2/ligand-dependent interaction between nuclear receptors and their coregulators is mediated by a short consensus motif, the so-called nuclear receptor (NR) box. Nuclear receptors exhibit distinct preferences for such motifs depending both on the bound ligand and on the NR box sequence. To better understand the structural basis of motif recognition, we characterized the interaction between estrogen receptor ␣ and the NR box regions of the p160 coactivator TIF2. We have determined the crystal structures of complexes between the ligand-binding domain of estrogen receptor ␣ and 12-mer peptides from the Box 2 and Box 3 regions of TIF2. Surprisingly, the Box 3 module displays an unexpected binding mode that is distinct from the canonical LXXLL interaction observed in other ligand-binding domain/NR box crystal structures. The peptide is shifted along the coactivator binding site in such a way that the interaction motif becomes LXXYL rather than the classical LXXLL. However, analysis of the binding properties of wild type NR box peptides, as well as mutant peptides designed to probe the Box 3 orientation, suggests that the Box 3 peptide primarily adopts the "classical" LXXLL orientation in solution. These results highlight the potential difficulties in interpretation of protein-protein interactions based on cocrystal structures using short peptide motifs. The estrogen receptor ␣ (ER␣)1 is a ligand-activated transcription factor that mediates the biological effects of the steroid hormone estrogen. Like other nuclear receptors (NRs), ER␣ exhibits a characteristic modular domain organization that includes two autonomous transcriptional activation functions (AF1 and AF2) that regulates transcription through interactions with NR coregulators (1-3). AF1, which resides in the N-terminal region of ER␣, is constitutively active and regulated by growth factors (4 -6). In contrast, AF2, which is located in the C-terminal ligand-binding domain (LBD) of ER, is entirely dependent on ligand for its activity.In recent years, structural and functional studies of both the AF2 domain of ER␣ and associated coregulators have greatly enhanced our knowledge of ligand-dependent, ER-mediated transcriptional activation. A large number of coactivators have been isolated that primarily target the LBD of the receptor in a ligand-and AF2-dependent manner (7,8). The most widely studied group of AF2 coactivators includes the p160 family of proteins (steroid receptor coactivator 1, TIF2/glucocorticoid receptor-interacting protein 1, and steroid receptor coactivator 3/AIB1) (9 -13) and the p300/cAMP-responsive element-binding protein-binding protein (14, 15). These factors possess intrinsic histone acetyltransferase activity and/or function in complexes with other acetyltransferases such as p300/cAMPresponsive element-binding protein-binding protein-associated factor (16, 17). They act to remodel chromatin through the regulation of histone acetylation status (18) and are therefore believed to influence promoter accessibility. The...

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Cooperativity and Dimerization of Recombinant Human Estrogen Receptor Hormone-binding Domain

Cited by 48 publications

References 32 publications

Oscillations and patterns in spatially discrete models for developmental intercellular signalling

Oscillations and patterns in spatially discrete models for developmental intercellular signalling

Structural Basis for Ca2+-induced Activation and Dimerization of Estrogen Receptor α by Calmodulin

Interaction of Transcriptional Intermediary Factor 2 Nuclear Receptor Box Peptides with the Coactivator Binding Site of Estrogen Receptor α

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